EVALUATION OF ATMOSPHERIC IMPACTS OF COATINGS VOCs

1. EVALUATION OF ATMOSPHERIC IMPACTS OF COATINGS VOCs William P. L. Carter CE-CERT, University of California, Riverside April 13, 2005 Outline • Background and Objectives • Environmental Chamber Experiments – Ozone Impacts • Environmental Chamber Experiments – PM Impacts • Exploratory Glycol Availability Experiments • Estimation of Hydrocarbon Solvent Reactivities • Direct Reactivity Measurement • Summary and Conclusions Atmospheric Impacts of Coatings VOCs

2. Recent UCR Coatings Reactivity Projects Evaluation of Atmospheric Impacts of Selected Coatings VOCs • CARB Contract 00-333 • Objective: Reduce uncertainties in estimations of ozone impacts of coatings VOCs • Final report at http://www.cert.ucr.edu/~carter/coatings Environmental Chamber Studies of VOC Species in Architectural Coatings and Mobile Source Emissions • SCAQMD Contract No. 03468 • Relevant Objectives: • Evaluate O3 impacts of selected water-based coatings VOCs • Determine PM impacts for Coating VOCs studied for CARB • Evaluate use of chamber for availability studies • Final report in preparation Atmospheric Impacts of Coatings VOCs

3. Components of Coatings Projects • Environmental chamber studies • Six complex hydrocarbon solvents and four water-based coatings VOC compounds chosen for study • UCR EPA chamber employed • Chamber results used to evaluate ozone reactivity predictions of the SAPRC-99 mechanism • PM measurement results used to derive qualitative estimates of relative PM impacts of solvents studied • Exploratory studies of effects of aerosol and humidity on glycol availability • Development and evaluation of general procedures to estimate reactivities of complex hydrocarbon solvents • Further development and evaluation of direct reactivity measurement methods Atmospheric Impacts of Coatings VOCs

4. Measurement or Calculationof Ozone Reactivities of VOCs • VOC Reactivities measured in chamber experiments are not exactly the same as VOC reactivities in the atmosphere. • Impractical to duplicate all relevant conditions • Chamber experiments have wall effects, static conditions, higher levels of test VOCs, etc. • Atmospheric Ozone impacts of VOCs must be calculated using computer airshed models, given: • Models for airshed conditions • Chemical mechanism for VOC’s Atmospheric Reactions • BUT mechanisms have uncertainties. reactivity calculations can be no more reliable than the chemical mechanism used. • Therefore, the purpose of chamber experiments is to test the ability of the mechanisms to predict reactivity in models Atmospheric Impacts of Coatings VOCs

5. Diagram of UCR EPA Chamber Atmospheric Impacts of Coatings VOCs

6. Photographs of Chamber and Lights Looking Towards Reactors (from light) Looking Towards Lights and Air Inlet Reflective walls and Ceiling Black Lights Arc Light Partially Filled Reactors Reflective walls Air Intake (Also one on other side) Atmospheric Impacts of Coatings VOCs

7. Incremental Reactivity Experiments • Objective is to determine effects of VOC’s reactions in chemical environments representing a range of atmospheric conditions. • Approach is to conduct two simultaneous experiments in the dual chamber • Base Case Experiment: Irradiate surrogate ROG – NOx mixture simulating an ambient chemical environment • Test Experiment: Same as base case experiment except that a test compound or solvent added • Effect of added VOC on O3, radicals, etc, provides a means to test model predictions reactivities of VOCs under similar conditions in the atmosphere • Base case experiments should reflect range of atmospheric chemical conditions relevant to VOC reactivity. Atmospheric Impacts of Coatings VOCs

8. Choice of Base Case forIncremental Reactivity Experiments • Major atmospheric chemical condition relevant to VOC reactivity is relative availability of NOx (relative ROG/NOx ratio). E.g., • Different aspects of the mechanism affect O3 impacts under different NOx conditions • High NOx experiments: test effects of VOCs on radical levels • Low NOx experiments: test effects of VOCs on NOx removal • Therefore, minimum of two base case experiments is needed Atmospheric Impacts of Coatings VOCs

9. Base Case Experimentsused in Coatings Reactivity Studies • NOx levels of 25-30 ppb, based on CARB recommendations of range of NOx that represents urban conditions in California • 8- component ROG surrogate (used previously) employed to represent major classes of VOCS present in ambient air • Formaldehyde removed in later experiments and other VOCs increased by 10% to simplify experiments • Calculated to give essentially the same reactivity results as base ROG mixture used to calculated reactivity scales. Atmospheric Impacts of Coatings VOCs

10. Experimental and Calculated O3 for Representative Base Case Experiments SAPRC-99 Model simulations of representative experiments Atmospheric Impacts of Coatings VOCs

11. Dependence of SAPRC-99 Underprediction Bias on Relative ROG/NOx Levels Atmospheric Impacts of Coatings VOCs

12. Aromatic Mechanism Adjustmentsto Improve Base Case Simulations • Biases in model simulations of base case experiment attributed to aromatics mechanism. So far, no aromatic mechanism found that gives satisfactory fits all the available chamber data. • Base case biases may cause biases in simulations of reactivity. • To investigate this, mechanisms for aromatics in the base ROG was adjusted to remove biases in base case simulations. • Yields of aromatic fragmentation products AFG2 and AFG3 for toluene and m-xylene increased by factor of 1.75 • Rate of reaction of AFG1 with O3 increased by factor of 10 • Comparing simulations with and without this adjustment shows effects base mechanism biases on reactivity predictions • Not a “better” aromatics mechanism because this adjustment makes fits to single aromatic – NOx experiments worse. Atmospheric Impacts of Coatings VOCs

13. Effects of Mechanism Adjustments on Simulations of Representative Experiments D([O3]-[NO]) (ppm) Atmospheric Impacts of Coatings VOCs

14. Effect of Aromatic Mechanism Adjustment on Base Case Model Underprediction Bias D([O3]-[NO]) Atmospheric Impacts of Coatings VOCs

15. VOCs Identified in the 2001 CARB Surveyof Water-Based Architectural Coatings Atmospheric Impacts of Coatings VOCs

16. Results of a Texanol® Injection Test Atmospheric Impacts of Coatings VOCs

17. OH Radical Rate ConstantsDerived from Chamber Data Atmospheric Impacts of Coatings VOCs

18. Reactivity Data for Texanol® Atmospheric Impacts of Coatings VOCs

19. Comparison of Chamber and AmbientReactivity Calculation For Texanol® Two curves almost on top of each other Atmospheric Impacts of Coatings VOCs

20. Reactivity Data for Butyl Carbitol Atmospheric Impacts of Coatings VOCs

21. Reactivity Data for Propylene Glycol Atmospheric Impacts of Coatings VOCs

22. Reactivity Data for Ethylene Glycol Atmospheric Impacts of Coatings VOCs

23. Glycol Decay Rates in Reactivity Runs: Comparison with Literature k(OH) Values Atmospheric Impacts of Coatings VOCs

24. Glycol Reactivity Data with aNon-Aromatic Surrogate Atmospheric Impacts of Coatings VOCs

25. Development of aBenzyl Alcohol Mechanism • Reaction with OH radicals assumed to dominate. • Single measurement of k(OH) given by Atkinson (1989) used • Reaction at -CH2OH, forming Benzaldehyde + HO2 assumed to occur 30% of the time, to fit benzaldehyde data in experiments • Mechanism of OH addition to ring based on that used for toluene • Overall nitrate yield adjusted to be 5% to give best fits to data • Benzaldehyde – NOx experiments also carried out to provide additional basis for developing adjusted mechanism. Atmospheric Impacts of Coatings VOCs

26. Reactivity Data for Benzyl Alcohol Atmospheric Impacts of Coatings VOCs

27. Simulations of Representative Benzaldehyde – NOx Experiments Atmospheric Impacts of Coatings VOCs

28. Summary of Mechanism Evaluation Resultsfor Water-Based Coatings VOCs * MIR of base ROG (Ambient Mixture) = 3.7 gm O3 / gm VOC Atmospheric Impacts of Coatings VOCs

29. Representative Hydrocarbon MixturesChosen For Reactivity Experiments Atmospheric Impacts of Coatings VOCs

30. Chemical Type Distributionsfor Hydrocarbon Mixtures Studied Atmospheric Impacts of Coatings VOCs

31. Reactivity Data for Dearomatized Mixed Alkanes (ASTM-1C) Atmospheric Impacts of Coatings VOCs

32. Comparison of Chamber and Ambient Reactivity Calculation for ASTM-1C Atmospheric Impacts of Coatings VOCs

33. Reactivity Data for Aromatic 100 Atmospheric Impacts of Coatings VOCs

34. Results for Other Petroleum DistillatesChange in D([O3]-[NO]) (ppm) Atmospheric Impacts of Coatings VOCs

35. Reactivity data for SyntheticHydrocarbon Mixture (ASTM-3C1) Atmospheric Impacts of Coatings VOCs

36. Assessment of Model Performance and MIRs for the Hydrocarbon Solvents Studied Atmospheric Impacts of Coatings VOCs

37. PM Measurements • Number densities of particles in 71 size ranges (28 - 730 nm) measured using a a Scanning Electrical Mobility Spectrometer • Data used to compute total particle number and volume (measured as mass assuming density of H2O) per unit volume • PM alternately sampled from each of the two reactors, switching every 10 minutes (15.3 data points/hour/reactor) • PM measurements made during most incremental reactivity experiments for the coatings projects • Background PM measurements made in experiments where PM precursors not expected • Seed aerosol not used in most experiments Atmospheric Impacts of Coatings VOCs

38. PM Data in Base Case Experiment Atmospheric Impacts of Coatings VOCs

39. PM Volume in Background Experiments 5 Hour PM Volume (mg/m3) Atmospheric Impacts of Coatings VOCs

40. Effects of Texanol® and the Glycolson 5-Hour PM Volume 5 Hour PM Volume (mg/m3) Atmospheric Impacts of Coatings VOCs

41. Effects of Hydrocarbon Solvents on5 Hour PM Volume 5 Hour PM Volume (mg/m3) Atmospheric Impacts of Coatings VOCs

42. Effects of Benzyl Alcohol and Butyl Carbitolon 5-Hour PM Volume 5 Hour PM Volume (mg/m3) Atmospheric Impacts of Coatings VOCs

43. Summary of PM Volume Reactivity Results Atmospheric Impacts of Coatings VOCs

44. Summary of PM Measurement Results • Background PM formation in chamber is up to ~1 mg/m3, depending on reactor employed • Probably due to contaminant reacting with OH, forming SOA • Reason for higher background in “A” reactor unknown • Secondary PM formation from ethylene and propylene glycol, Texanol®, and the ASTM-3C1 synthetic mixture negligible. • Small but measurable PM from petroleum distillate solvents. Not simply related to aromatic content. • Highest secondary PM from butyl carbitol and (especially) benzyl alcohol • Chamber effects PM model needed before PM data can be used for quantitative mechanism evaluation Atmospheric Impacts of Coatings VOCs

45. Glycol Availability Screening Experiments Objective • Determine if added aerosols affect gas-phase consumption rates and reactivities of glycols Experiments Carried Out • Dark decay experiments with ethylene and propylene glycol with 10 g/m3 (NH4)2SO4 seed aerosol at 35% RH. • ROG – NOx ambient surrogate irradiation with added propylene glycol with 9 g/m3 (NH4)2SO4 seed aerosol at 25% RH. • ROG – NOx ambient surrogate irradiation with added ethylene glycol with 7 g/m3 NH4HSO4 seed aerosol at 30% RH. • Note: Aerosol and humidity added to only one reactor because of limited aerosol generation and humidification capacity. Atmospheric Impacts of Coatings VOCs

46. Results of Glycol Dark Decay Experiment Atmospheric Impacts of Coatings VOCs

47. Effects of Aerosol and Humidity on Glycol Reactivity Experiments Model calculations used adjusted aromatics base mechanism for best fits. No base data in added aerosol runs because of limited humidification and aerosol generation capacity. D([O3]-[NO]) (ppm) Atmospheric Impacts of Coatings VOCs

48. Glycol Decay Rates in Availability Runs: Comparison with Literature k(OH) Values Atmospheric Impacts of Coatings VOCs

49. Glycol Availability Experiments:Preliminary Conclusions • No clear effect on glycol consumption rate or ozone reactivity for humidity up to 35% and (NH4)2SO4 or NH4HSO4 seed aerosol up to 10 mg/m3. • But there still may be a measurable effect at higher humidity or aerosol concentration, with a different type of aerosol • Upgrades are being made to the chamber facility to facilitate experiments at higher RH, aerosol levels. • But experiments that measure increases in aerosol mass when exposed to gas-phase VOCs may give a more sensitive measure of VOC uptake on aerosols Atmospheric Impacts of Coatings VOCs

50. Evaluation of Methods to Estimate Complex Hydrocarbon Solvent Reactivities • MIRs for complex hydrocarbon solvents currently estimated using a “binning” procedure based on correlations between carbon numbers, type distributions, and MIRs • Bin MIRs evaluated by comparison with MIRs calculated using detailed compositional data for a wide variety of solvents • Agree within 25% except for bins with light cycloalkanes • An alternative “spreadsheet” method developed for deriving estimated compositions for solvents with limited data • Separates compositional and reactivity estimates. Permits derivations in reactivities for other scales besides MIR. • Agrees with calculations using detailed compositional data within 10% in most cases • Can be used as a basis for updating hydrocarbon bin reactivities when reactivity scale is changed or updated. Atmospheric Impacts of Coatings VOCs